Universal remote radio unit bird armored fiber optic cable assembly

ABSTRACT

A fiber optic cable has a cable core that includes at least one optical fiber coupled to a fiber optic connector. A cable adapter sleeve is axially mounted on the cable core to surround the cable core, the cable adapter sleeve including a body portion that has a first outer diameter and a collar that has a second outer diameter that is greater than the first outer diameter. A crush sleeve is seated within a crush groove of the collar.

BACKGROUND

1. Field of the Invention

This invention relates to fiber optic and hybrid electro-optical cableassemblies. More particularly, the invention relates to cable assembliesadaptable to a variety of different remote radio unit conductor entrydimensional specifications.

2. Description of Related Art

The wireless communications industry is changing from traditional signaldelivery from ground based transceivers delivering/receiving the RFsignal to/from the antenna atop the radio tower via bulky/heavy/highmaterial cost semi-rigid metal RF coaxial cable to optical signaldelivery to a tower top mounted transceiver known as a remote radio unit(RRU) or remote radio head (RRH) with implementation of fiber to theantenna (FTTA) cabling.

As this area of the market is evolving quickly, many original equipmentmanufacturers (OEM) are providing different RRU/RRH with differenttermination requirements, requiring different fiber optic cableassemblies with different cable outer diameter (OD) and breakoutlengths. For example, even when the RRU/RRH are from the same OEM, therequired cable assemblies may have different requirements.

One requirement may be for a shorter breakout length wherein theconnectorized breakout is captive and connectorized inside a smallcavity of the RRU enclosure, for example, via a rubber gland that sealsonly against 5 mm OD cable. Alternatively, the OD may be, for example, 6or 7 mm and the connector connectorized with another connector that ison an outside plate of the RRU. This larger diameter OD receivingconnector may also seal against the OD of the larger diameter cable.

In regions where tropical birds such as cockatoos may be present, towermounted cable assemblies may be provided with an armoring to resistcrushing or tearing damage inflicted by the powerful beaks of thesebirds. Providing the cables with a crush sleeve of sufficient diameterto prevent a bird from taking the cable in its beak to apply a tear orcrush force may be effective for preventing beak damage. However, largediameter cable sleeving may require elaborate and therefore expensivetermination assemblies such as equipment specific collars and/or gasketsto avoid leaving a bare end of the crush sleeve open for the birds toengage.

Factory terminated hybrid cable assemblies are known. Furcation tubesmay be applied to fibers and or fiber bundles stripped back from thecable end to protect the optical fibers from damage between the cableand the optical fiber termination. Optical fiber furcation tubes mayconsist of an inner polymer tube surrounded by a para-aramid syntheticfiber sheath, or a para-aramid synthetic fiber sheath alone.

Therefore, an object of the invention is to provide optical and/orelectro-optical cable solutions that overcome deficiencies in the priorart.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate embodiments of the invention,where like reference numbers in the drawing figures refer to the samefeature or element and may not be described in detail for every drawingfigure in which they appear and, together with a general description ofthe invention given above, and the detailed description of theembodiments given below, serve to explain the principles of theinvention.

FIG. 1 is a schematic isometric view of an exemplary cable assembly.

FIG. 2 is a schematic isometric view of an exemplary cable adaptersleeve.

FIG. 3 is a schematic cut-away side view of the cable adapter sleeve ofFIG. 2 installed upon a cable core with an armor tube.

FIG. 4 is a schematic isometric view of an alternative cable adaptersleeve.

FIG. 5 is a schematic cut-away side view of the cable adapter sleeve ofFIG. 5 installed upon a cable core with an armor tube.

FIG. 6 is a schematic isometric view of an RRU gasket.

FIG. 7 is a schematic cut-away side view of the RRU gasket of FIG. 6,seated upon the cable adapter and cable core of FIG. 5.

FIG. 8 is a schematic side view of a cable end corresponding to FIG. 7.

FIG. 9 is a schematic isometric view of an alternative RRU gasket.

FIG. 10 is a schematic partial cut-away side view of the gasket of FIG.9 seated upon a cable adapter and cable core.

FIG. 11 is a schematic isometric view of an exemplary cable assemblywith a crush sleeve.

FIG. 12 is a schematic partial cut-away side view of the cable assemblyof FIG. 11.

FIG. 13 is a schematic close-up view of the cable adapter sleeve portionof FIG. 12.

FIG. 14 is a schematic close-up view of the sleeve seat portion of FIG.12.

FIG. 15 is a schematic isometric view of an alternative embodiment cableadapter sleeve.

FIG. 16 is a schematic cut-away side view of the cable adapter sleeve ofFIG. 15.

FIG. 17 is a schematic isometric view of a furcation bore embodiment ofa cable adapter sleeve.

FIG. 18 is a schematic cut-away side view of the cable adapter sleeve ofFIG. 17.

FIG. 19 is a schematic partial cut-away close-up view of the cableadapter sleeve of FIG. 17, installed upon a cable core that is furcatedin the furcation bore.

FIG. 20 is a schematic isometric partial cut-away view of cable adaptersleeve embodiment for slot and clip crush sleeve retention.

FIG. 21 is a schematic side view of a clip for use with the cableadapter sleeve of FIG. 20.

FIG. 22 is a schematic isometric cable end view of the cable adaptersleeve of FIG. 20.

FIG. 23 is a schematic isometric view of a cable assembly with slot andclip crush sleeve retention.

FIG. 24 is a schematic isometric partial cut-away side view of the cableadapter sleeve of FIG. 20 seated upon a crush sleeve, retained by theclip of FIG. 21.

DETAILED DESCRIPTION

The inventor has recognized that it is time consuming, hazardous andexpensive to install new cable assemblies on a tall radio tower. Asingle user may utilize different types of RRU/RRH. To avoid duplicationof incompatible assemblies and simplify sourcing for the user, a singlesolution that can be used with multiple types of RRU/RRH has beendevised. Thereby, should the rapidly evolving RRU/RRH technology adoptone or the other interconnection/sealing interfaces as a standard and/orthe user select the alternative RRU/RRH in the future, the RRU/RRH maybe easily exchanged in the future without also requiring exchange of theentire cable assembly.

These cable assemblies may include adapter sleeves which include aplurality of differently dimensioned outer diameter surfaces and otherfeatures, to allow the same cable assembly to be used with a variety ofdifferent RRU/RRHs, despite the differences in connection mechanisms onthese various different RRU/RRHs.

A fiber optic cable 100, for example as shown in FIG. 1, includes a pairof cable cores 110 that each include a first and a second optical fiber112. A first fiber optic connector 120 and a second fiber opticconnector 130 are provided at respective ends of each of the cable cores110. A portion of each cable core 110 may be protected by a protectivearmor tube 140. It is the respective armor tubes 140 that are sealedagainst by the environmental seals of the RRU/RRHs.

The first and second optical fibers 112 may be single mode opticalfibers, multi-mode optical fibers, etc. The first and second opticalfibers 112 may be 900 micron buffered or 250 micron buffered opticalfibers. The cable core 110 may be a loose tube cable, a ribbon cable orany other appropriate core configuration. In other words, the cable core110 may be any suitable fiber optic cable core and, as discussed herein,may also include other elements such as one or more metal electricalconductors. In the exemplary embodiment demonstrated by FIG. 1, thefirst and second optical fibers 112 comprise buffered single modeoptical fibers that run adjacent to each other in the cable core 110.Alternatively, the fibers may be single fiber strands. At the first endof the cable 100, the first and second optical fibers 112 split apartfrom each other at a first optical connector 120 provided as a duplex LCconnector. In the depicted embodiment, each buffered optical fiber 112may have an outer diameter of about 0.9 mm, although other sized opticalfibers may be used. One of the optical fibers 112 may be used to carrysignals that are to be transmitted from the antenna associated with theRRU/RRH while the other of the optical fibers 112 may be used to carrysignals that are received at the antenna to the remainder of the basestation equipment.

The first and second fiber optic connectors 120, 130 may each compriseany appropriate fiber optic connector including, for example, an LC, SC,or MPO connector.

In the depicted embodiment, the first and second fiber optic connectors120, 130 are each implemented as a duplex LC connectors.

The protective armor tube 140 may comprise, for example, a polyethylenetube having an outer diameter of, for example, between about 6 mm andabout 12 mm. In some embodiments, the outer diameter of the protectivearmor tube 140 may be sized to be received within a cable clamp that isprovided on at least one of the RRU/RRHs with which the cable 100 is tobe used. As will be discussed in further detail below, some RRU/RRHssuch as, for example, a RRU-S01 manufactured by Ericsson Inc., PlanoTex., may have a gland that covers the fiber optic connector port on theRRU/RRH. This gland may provide an environmental sealing function (e.g.,to reduce or prevent water or moisture ingress into the connector portarea and/or into the RRU/RRH) and may also provide a strain relieffunction to prevent the cable 100 or the connector port on the RRU frombeing damaged if a pulling force is applied to the cable 100. The abovereferenced gland on the RRU may have a clamp that is designed to receivea certain diameter cable in order to provide the strain relieffunctionality. Thus, the protective armor tube 140 may have a diameter(e.g., about 6 mm to about 12 mm) that is designed to fit within thestrain relief clamp on the gland of the RRU. The protective armor tube140 may also provide enhanced protection to the optical fibers 112, 114in the section of the cable 100 that is at the top of the tower wherethe RRU may be located, which is a portion of the cable 100 that may bemore susceptible to being damaged.

A cable adapter sleeve 150, for example as shown in FIG. 2, is providedpositioned axially on the cable 100. The cable adapter sleeve 100 mayserve multiple functions including, for example, providing a differentouter diameter in the region of the cable 100 adjacent the connector 120that may be used to mate the cable 100 with additional types ofRRU/RRHs. The cable adapter sleeve 150 may also perform a strain relieffunction. As shown best in FIG. 2, the cable adapter sleeve 150 includesa body portion 152, a collar 154 and a stop 156. The cable core 110extends through all three of the body portion 152, the collar 154 andthe stop 156. The collar 154 extends from the rear end of the bodyportion 152. The collar 154 may be formed integrally with the bodyportion 152 or as a separate piece that is attached to the body portion152. As best shown in FIG. 3, the collar 154 is fitted over one end ofthe protective armor tube 140. The stop 156 extends from the other(front) end of the body portion 152. The stop 156 may also be formedintegrally with the body portion 152 or as a separate piece that isattached to the body portion 152. The first and second optical fibers112 extend all of the way through the stop 156 for insertion into therespective boots of the dual-boot duplex LC connector 120. The cableadapter sleeve 150 may comprise, for example, a polymer sleeve, a metalsleeve or a combination thereof.

The cable adapter sleeve 150 may be formed as a unitary single-pieceadapter sleeve. The cable adapter sleeve 150 may be formed, for example,by injection molding, machining or any other appropriate manufacturingprocess, including in situ overmolding molding of materials such as TPEor silicon, around the cable core and an end of the protective armortube 140. The cable adapter sleeve 150 may be generally cylindrical,with several separate portions of different circular cross-sectiondiameters. The central body portion 152 may have a relatively smallcross-sectional outer diameter, for example, of about 5 mm. The collar154 may have a larger cross-sectional outer diameter, which in thedepicted embodiment is about 12 mm, which allows the collar 154 to fitover the end of the protective armor tube 140 which has an outerdiameter of about 10 mm. The stop 156 is a “two step” stop that has twodifferent cross-sectional outer diameters: namely, a cross-sectionalouter diameter of about 11 mm for the larger step 158 and across-sectional outer diameter of about 5 mm for the smaller step 159.Some RRU/RRHs include a rubber gasket that covers and protects the fiberoptic connector port on the RRU/RRH, and thus it is necessary to insertthe end of the cable 100 that includes fiber optic connector 120 throughthis rubber gasket to be received within the fiber optic connector porton the RRU/RRH. The increased cross-sectional outer diameters of thestop 156 may engage a back surface of the rubber gasket in order tofunction as a strain relief mechanism that resists axial forces that mayotherwise pull the fiber optic connector 120 out of the mating fiberoptic connector port on these RRU/RRHs.

The body portion 152 of cable adapter sleeve 150 is a tubular body thathas a central passageway 153 that the first and second optical fibers112 extend through. The collar 154 likewise has a tubular shape, but thecentral passageway 155 of the collar 154 may have a significantly largerinternal diameter that may be sized, for example, to receive an end ofthe protective armor tube 140. An adhesive may be coated onto theoutside of the protective armor tube and/or onto the interior surface ofthe passageway 155 in order to bond the protective armor tube 140 withinthe passageway 155 of the collar 154. The collar 154 may also include anaperture 160 that may receive a protrusion that is included on thegaskets that are included on some RRU/RRHs. By inserting this protrusioninto the aperture 160, an improved seal and/or improved strain reliefmay be provided. The stop 156 may have an internal passageway 157 thatis, for example, the same diameter as the internal passageway 153 of thebody portion 152.

The outer diameter of the collar 154 may, in some embodiments, be sizedto fit within a clamp for one or more different types of RRU/RRHs. Forexample, an RRU that is manufactured by Alcatel-Lucent, Murray Hill,N.J., has a clamp that is sized to receive a cable having an outerdiameter of about 12 mm. The increased outer diameter of the collar 154may be sized to fit within the clamp on the Alcatel-Lucent RRU so thatthe cable 100 may be properly connected to the Alcatel-Lucent RRU withfull sealing and strain relief protection.

The outer diameter of the body portion 152 may, in some embodiments, besized to fit a gasket or other aperture that provides access to theconnector port on other types of RRU/RRHs. For example, the RRU-S11 andRRU-S12 RRU that are manufactured by Ericsson each include a gasket thatis sized to receive a cable having an outer diameter of about 5 mm. Thestop 156 may be passed through this gasket and may contact a back sideof the gasket (i.e., the side of the gasket facing the RRU). Theincreased outer diameter of the stop 156 may be sufficiently large thatit may be difficult to pull the collar through the gasket, and hence thestop 156 may perform a strain relief function for the cable 100 when thefiber optic connector 120 of cable 100 is received within a fiberoptical connector port on either of the Ericsson RRU-S11 or RRU-S12 RRU.The body portion 152 may have an outer diameter that allows the gasketto properly perform its sealing function.

As best shown in FIG. 3, a first annular groove 162 of the stop 156,open to the body portion 152, may be provided as a seat of an end of thegasket, for retaining the gasket immediately prior to mating with theRRU/RRH. In further embodiments, for example as shown in FIGS. 4 and 5,a second annular groove 164 of the collar 154, open to the body portion152, may be applied, for improved gasket retention. The first and/orsecond annular grooves 162, 164 may be provided as a straight or taperedbore. Thereby, a gasket 166, for example as shown in FIG. 6, may beapplied and retained by the first and second annular grooves 162, 164 asshown for example in FIGS. 7 and 8.

Alternatively, as shown in FIGS. 9 and 10, the collar 154 may also beprovided with a gasket seat 168 at a cable end, provided with a diametergreater than the body portion 152 but less than the collar 154. Therebya gasket 166 dimensioned to seat against the gasket seat 168 has ashoulder provided by the collar 154, operative again as a stop shoulder,preventing axial movement of the cable adapter sleeve 150 and thus theattached armor tube 140 out of the RRU/RRH when tension is applied fromthe cable end.

In the depicted embodiment, the axial cross-sections through the bodyportion 152, collar 154 and stop 156 are all substantially circularcross-sections, which facilitates inserting these portions of the cableadapter sleeve 150 within different clamps, gaskets and the like oncommercially available RRU/RRHs so that proper sealing and strain reliefmay be provided when the cable 100 is connected to various of theseRRU/RRHs. It will be appreciated, however, that other cross-sectionaldiameters may alternatively be used, particularly if appropriate for theclamp and gasket designs (and/or the designs of other features) on theseRRU/RRHs.

Thus, as discussed above, it will be appreciated that the cable adaptersleeve 150 includes multiple sections having different cross-sectionalouter diameters that may be received within different sized clamps,gaskets and the like on RRU/RRHs in order to facilitate using the cable100 with a variety of different RRU/RRHs. The cable adapter sleeve 150may be located adjacent the fiber optic connector 120 so that it willproperly mate with the different sealing, clamping and/or strain reliefcomponents on the various RRU/RRHs. For example, in some embodiments,the front portion of the cable adapter sleeve (i.e., the portion of thecable adapter sleeve 150 that includes the stop 156) may be in the rangeof about 80 mm to about 350 mm from the front of the fiber opticconnector (which is the forward most part of cable 100). The bodyportion 152 may need to have a minimum length so that the body portion152 will properly fit through the aperture in the gaskets provided onvarious RRU/RRHs.

In further embodiments, for example as shown in FIGS. 11-14 and 23-24,the cable core 110 and armor tube 140 may be further protected byinserting the armor tube 140 within a crush sleeve 180 of sufficientdiameter to protect against damage from crushing or tearing by birdbeaks. In particular, while other diameters may be appropriate for thespecific bird species common to the region where the installationoccurs, a diameter of at least 19 millimeters has been demonstrated aseffective for preventing beak damage from cockatoos. Because the crushsleeve 180 is dimensioned to be too large for the bird to place its beakaround, the crush sleeve 180 may not be required to have a strengthcharacteristic sufficient to withstand the full potential crush force ofthe bird beak, enabling the crush sleeve 180 to be formed from cost andweight-efficient materials, such as polymer tubing. To improve the bendradius of the crush sleeve 180, the crush sleeve 180 may be providedwith annular or helical corrugations 181.

The crush sleeve 180 may be coupled to the cable adapter sleeve 150 viainsertion within an annular crush groove 182 provided in the collar 154.The other end of the crush sleeve 180 may be terminated withoutaccessible edges of the crush sleeve 180, for example, via insertioninto a cylindrical sleeve seat 184, the sleeve seat 184 surrounding thedesired connection interface 186, demonstrated in FIGS. 11, 12, 14 and23 as an ODC-type fiber optic connector. As best shown in FIG. 14. thesleeve seat 184 may key with the connection interface 186, for examplevia an inward projecting lip 188 which seats within a seal groove 190provided on an outer diameter of the connection interface 186.

In embodiments with a crush sleeve 180 seated in the crush groove 182,the outer surface of the collar 154 also utilized for the gasket seat168 may have an incompatible diameter. To provide the functionality of agasket seat 168 in addition to the crush sleeve 180, the gasket seat 168may be provided forward of the collar 154, for example as shown in FIGS.15 and 16.

The cable adapter sleeve 150 may also be provided with a furcation bore191 at the connector end of the internal passageway 157, for example asshown in FIGS. 18-20 and 23, for seating/encapsulating a furcation ofoptical fibers 112 from the cable core 110 into separate first opticalconnectors 120. The furcated ends of the cable core seated in thefurcation bore 191 may be encapsulated via, for example, epoxy and/oradhesive injection through an aperture 160.

Because the cable core 110 and/or armor tube 140 remains sealed viainsertion into the central passageway 155 at one end and at the selectedtermination at the other end of the assembly, a fully environmentallysealed termination of the crush sleeve 180 may not be required at eachend. As such the coupling between the crush sleeve 180 and the cableadapter sleeve 150 and/or at the other end of the assembly may be freefloating within the respective crush groove 182 and/or sleeve seat 184.Alternatively, adhesives and/or sealants may be applied, for example byinjection through an aperture 160 of the collar 154 which opens into thecrush groove 182.

An embodiment demonstrating an unsealed mechanical retention of thecoupling between the crush sleeve 180 and the cable adapter sleeve 150is shown in FIGS. 20-24. The outer diameter of the collar 154 may beprovided with a plurality of slots 192 dimensioned to receive inwardprojections 194 of a clip 196. Upon seating the clip 196 upon the slots192, the inward projections 194 extend into the crush groove 182 to keywith the corrugations 181 of the crush sleeve 180, longitudinallyinterlocking the crush sleeve 180 with the cable adapter sleeve 150. Aslot and clip retention with the corrugations 181 of the crush sleeve180 may also be applied between the sleeve seat 184 and crush sleeve180, as shown for example in FIG. 23.

One skilled in the art will appreciate that the crush sleeve 180termination into the crush groove 182 provides a circumferential seatfor the crush sleeve 180 that does not leave an edge of the crush sleeveend accessible to bird beaks. However, the cable adapter sleeve 150 isstill suitable for sealing against the small diameter openings of thevarious RRU/RRHs.

To prevent the transition from the oversized diameter of the collar 154to the relatively small diameter of the body portion 152 from becoming aweak point of the armored fiber optic cable assembly, the cable adaptersleeve 150 may be provided formed from a material with suitablyincreased strength characteristics, such as fiber reinforced plastic ormetal.

Returning to FIG. 1, one skilled in the art will appreciate that thecable adapter sleeves 150 may be applied to a single fiber conductorcable or to multiple armor tubes 140 of a multi-conductor cable whichmay include a plurality of optical cable cores 110 to be separatelyterminated. The multi-conductor cable may further include electricalconductors 170, the electrical conductors 170 provided with a shieldedfurcation tube 172 and a shield layer to multi-conductor cable shieldinterconnection at a transition housing 174 where the cable cores 110are also broken out into their respective armor tubes 140. Shieldedfurcation tubes 172 and interconnections between the shield layer 176 ofthe shielded furcation tube 172 and the shield 178 of themulti-conductor cable are disclosed in detail in commonly owned U.S.patent application Ser. No. 13/791,248, “Shielded Electrical ConductorFurcation Assembly”, filed 8 Mar. 2013 by Nahid Islam, herebyincorporated by reference in its entirety. The number of optical and/orelectrical conductors present in the may be selected as desired,according to the intended installation.

While the cables and cable adapter sleeves according to embodiments ofthe present invention have primarily been discussed above with respectto their use on RRU/RRHs, it will be appreciated that there may be otherapplications such as enclosure units and the like in which the fiberoptic cables and cable adapter sleeves according to embodiments of thepresent invention may be used in order to provide universal cables thatmay be used with multiple of such units that have different cableclamping, sealing and/or strain relief designs.

One skilled in the art will appreciate that the application of the cableadapter sleeve enables a single cable assembly to be used with a widerange of RRU/RRH equipment, enabling simplified cable assemblymanufacture, inventory, procurement and/or field exchange of equipment.

Table of Parts 100 cable 110 cable core 112 optical fiber 120 firstoptical connector 130 second optical connector 140 armor tube 150 cableadapter sleeve 152 body portion 154 collar 155 passageway 156 stop 157internal passageway 158 larger step 159 smaller step 160 aperture 162first annular groove 164 second annular groove 166 gasket 168 gasketseat 170 electrical conductor 172 shielded furcation tube 174 transitionhousing 176 shield layer 178 shield 180 crush sleeve 181 corrugation 182crush groove 184 sleeve seat 186 connection interface 188 lip 190 sealgroove 191 furcation bore 192 slot 194 inward projection 196 clip

Where in the foregoing description reference has been made to materials,ratios, integers or components having known equivalents then suchequivalents are herein incorporated as if individually set forth.

While the present invention has been illustrated by the description ofthe embodiments thereof, and while the embodiments have been describedin considerable detail, it is not the intention of the applicant torestrict or in any way limit the scope of the appended claims to suchdetail. Additional advantages and modifications will readily appear tothose skilled in the art. Therefore, the invention in its broaderaspects is not limited to the specific details, representativeapparatus, methods, and illustrative examples shown and described.Accordingly, departures may be made from such details without departurefrom the spirit or scope of applicant's general inventive concept.Further, it is to be appreciated that improvements and/or modificationsmay be made thereto without departing from the scope or spirit of thepresent invention as defined by the following claims.

We claim:
 1. An armored fiber optic cable mateable with a plurality ofremote radio unit configurations, comprising: a cable core that includesat least one optical fiber; a fiber optic connector that receives the atleast one optical fiber; a monolithic cable adapter sleeve seated uponthe cable core; the cable adapter sleeve including a body portion thathas a first outer diameter and a collar that has a second outer diameterwhich is greater than the first outer diameter; an armor tube seatedupon the cable core having a fourth outer diameter that is greater thanthe first outer diameter but less than the second outer diameter, thearmor tube coupled to an internal passageway of the collar; and a crushsleeve surrounding the armor tube having a fifth outer diameter that isgreater than the fourth outer diameter, the crush sleeve coupled to acrush groove of the collar.
 2. The fiber optic cable of claim 1, furtherincluding a stop on the cable adapter sleeve that has a third outerdiameter that is greater than the first outer diameter.
 3. The fiberoptic cable of claim 2, further including a first annular grove providedin the stop, the first annular groove open to the body portion.
 4. Thefiber optic cable of claim 2, wherein the stop, the body portion and thecollar have circular cross-sections.
 5. The fiber optic cable of claim1, wherein an outer diameter of the crush sleeve is at least 19millimeters.
 6. The fiber optic cable of claim 1, further including asecond annular groove provided in the collar, the second annular grooveopen to the body portion.
 7. The fiber optic cable of claim 1, whereinthe collar includes an aperture extending between an outer diameter ofthe collar and a passageway of the collar.
 8. The fiber optic cable ofclaim 1, wherein the collar has a gasket seat at a cable end that has afourth outer diameter which is greater than the first outer diameter andless than the second outer diameter.
 9. The fiber optic cable of claim1, wherein the first outer diameter of the body portion of the cableadapter sleeve is sized to sealingly fit within a gasket on a secondremote radio unit.
 10. The fiber optic cable of claim 1, wherein thesecond outer diameter of the collar of the cable adapter sleeve isconfigured to be received within a clamping structure of a third remoteradio unit.
 11. The fiber optic cable of claim 1, wherein the fiberoptic cable further includes at least one electrical conductor.
 12. Thefiber optic cable of claim 1, wherein a front of the fiber opticconnector is positioned between about 80 mm and about 350 mm from afront of the collar of the cable adapter sleeve.
 13. A method formanufacturing an armored fiber optic cable mateable with a plurality ofremote radio unit configurations, comprising: providing a cable corethat includes at least one optical fiber; coupling a fiber opticconnector to the at least one optical fiber; mounting a monolithic cableadapter sleeve axially on the cable core, the cable adapter sleeveincluding a body portion that has a first outer diameter and a collarthat has a second outer diameter greater than the first outer diameter;coupling an armor tube to an internal passageway of the collar, thearmor tube provided with a fourth outer diameter that is greater thanthe first outer diameter but less than the second outer diameter; andproviding a crush sleeve surrounding the armor tube; the crush sleeveprovided with a fifth outer diameter that is greater than the fourthouter diameter, the crush sleeve coupled to a crush groove of thecollar.
 14. The method of claim 13, wherein the crush sleeve is coupledto the crush groove by inserting an inward projection of a clip througha slot of the collar so that the inward projection keys with acorrugation of the crush sleeve.
 15. The method of claim 13, wherein thecable adapter sleeve further includes a stop that has a third outerdiameter that is greater than the first outer diameter.
 16. The methodof claim 13, wherein the cable adapter sleeve is mounted by overmoldingthe cable adapter sleeve upon an outer diameter of the cable core. 17.The method of claim 13, wherein the cable adapter sleeve is mounted bypassing the cable core through a passageway of the cable adapter sleeveand gluing the cable adapter sleeve at a desired axial position onto anouter diameter of the cable core.
 18. The method of claim 13, whereinthe cable adapter sleeve is mounted such that a front of the fiber opticconnector is positioned between about 80 mm and about 350 mm from afront of the collar of the cable adapter sleeve.
 19. The method of claim13, further including at least one electrical conductor in the cable.20. The method of claim 13, wherein the cable adapter sleeve is formedof a metal material.